Liquid level gauge



April 13, 1954 D. c. BRUNTON ETAL LIQUID LEVEL GAUGE 3 Sheets-Sheet 1 Filed July 27 1951 April 13, 1954 D, c. BRUNTON ETAL LIQUID LEVEL GAUGE 3 Sheets-Sheet 2 Filed July 2'?, 1951 fwerors DONALD C. BRUNTON @y NORMAN Z. ALCOCK I;%`'AM' April 13, 1954 D. c. BRUNTON Erm.

LIQUID LEVEL GAUGE 3 Sheets-Sheet 3 Filed July 27 1951 DONALD C. BRUNTON @r NoRMAm/( Patent'ed Apr. 13, 1954 UNITED lSTATES ATENT OFFICE LIQUID LEVEL GAUGE Application Ju1y`27, 1951, Serial No. 238,880

1 This invention relates to a'method of andai?- par'atu's for obtaining information concerning lan object by rconverting gamma or beta radiation coming 'therefrom'tolight energy and converting the latter to electrical energy to actuate an indicator.Y` More specifically the invention concerns a device rfor determini-ngthe presence or level 'of a substance ina container formed of a different Substance.-

-In prior- -methods' *of 'determining information with-'respect toen-object by utilizing radio-active source lin' combination with detecting 'means for determining' thet physical characteristics of the Object -fro'rn-theresiiltiri'g radiation coming theref-r'o'm','the` source-employed has in rnostl cases been radium fof an vactivity v`of about-one mllicurie. In'nearlly all cases Geiger counters and ionization chambers have been employed as detecting devices'. Aninherentcharacteristic of such systenis and methods istne low activity of the source and low eiiciency of the detector' whereby necessaryfstatistical vaccuracy vusually requires a time element of theforder oftw'enty seconds for any one-f-indicationor measurement. Such prior devices'and methods 'may be improved in eiliciency bymodicat-ion tri-handle large amounts of radiation but such modification is necessarily accompanied lby an increase finbulk in the equipmentwhich becomes rim'practical from a portable aspect if a short time delay in readings and desirable efficiencies are to 'be arrived at.

It is lthe'main object of the present invention to provide a device and method for determining information concerning an Iobjectby radiation technique wherein the eiiicien'cy is of the order of ten-to one hundred 'tin'fiesv that' previously obtainable by easily portable equipment.

Another eb'ject vof `therirnf'ertion is 'to provide a'devic'e'and methodes before wherein the source is of an activity between live and fifty m-ill-icuries when excited by 'b'eta or gamma radiation Claims. (Cl. Z50-43.5)

, light energy to a photo-sensitive device which converts the light energy to electrical energy i'n the forni of signal pulses corresponding to radiation pulses coming from the position of the object being examined. The electrical signal pulses are applied to an electrical resistor and vcapacitor disposed electrically in parallel, the latter being of a time constant preferably greater than onet-enth of a second. The resistor and capacitor act to convert the signal pulses substantially to a non-pulsating direct current signal which is proportional to the mean value of the signal pulses. In particular, the invention contemplates a method and means for removing 'an undesired component of the direct currentsignal corresponding for example to the Wall of a vessel containing a material, the level of which is desired to be measured by applying the necessary biasing to the direct current signal. Indicating means responsive to the resulting direct current signal may be of any simple form and may in some instances indicate not only the presence-of such residual direct current signal but also its magnitude.

Other objects of the invention will be appreciated by a study of the following specification taken in conjunction with the accompanying drawings.

In the drawings,

Figure 1 is a general schematic of the essentials o apparatus according to the invention of that class adaptable for determining'the level or a material in a vessel.

Figure 2 is an electrical schematic of one spe'- ciiic form of detector head according' to the iii*- vention.

Figures 3 and 4 are sectional views of themechanical construction of the detector head of Figure 2.

Figure 5 is an electronic circuit diagram of one practical form of unit which may be employed with the detector head of Figures 2 to 4 in measuring the level of material within a Vessel but which has multiple amplifiers eliminated therefrom for Simplicity in illustration.

In Figure 1 a general layout of vthe essentials of a system according to the invention is illustrated wherein the detector head Ill is of a character particularly adapted to the measuring of the level of a material within a vessel having a Wall Il. The detector head comprises a source I2 preferably emitting gamma radiation of an activity between ve and fifty millicuries and preferably twenty millicuries. The source is imbedded in a body of lead I3 acting as a shield and having a diverging slot I4 therein serving to direct the radiation pulses, in the paths indicated by the arrows RI. Certain of these rays may reflect off the wall II by the path RI1 but which must pass through a barrier portion I5 of the body I3 before passing into the fluorescent body I. Other rays of radiation from the source I4 may be reflected from material within the vessel in the direction of the arrows R2 to enter the uorescent body IS.

As hereinafter disclosed in more detail, the slot Id of the lead body I3 is of such character that the emission beam is of small depth so that the upper limits of material within the vessel can be critically determined by the position of the detector head on the vessel wall. Where the detector head is in a position above the material in the vessel only the rays R21 are reflected to the iuorescent body i5 from the vessel wall I l The fluorescent body is of that class which is substantially transparent to its own light energy. Examples of such materials are:

Napthalene Antracene Stilbene Terphenyl Sodium iodide (thallium impregnated) Potassium iodide (thallium impregnated) Calcium tungstate Light energy directed in the path L strikes a photo-sensitive device l1 adapted to convert the light energy to electrical energy in the form of a pulsating direct current signal hereinafter referred to as signal pulses of a mean magnitude Eo. The photo-sensitive device is connected by suitable lead i8 to an amplier I9, both the photo-sensitive device Il and the amplifier I9 being connected to the grounded line 20. The signal pulses of a mean voltage Value E01 are developed from the amplifier and are applied to the resistor 2l and condenser 22 disposed electrically in parallel between a battery source biasing means 23 and the signal connecting line 24. The resistor-condenser combination is of a time constant preferably greater than one-tenth of a second and serves to smooth out the pulsating direct current of the signal to deliver an effective direct current signal of substantially non-pulsating characteristics of a magnitude Vo corresponding to the sum of VI plus V2 wherein VI corresponds in its magnitude to the mean value of that portion of the signal pulses representing reflected radiation RI1 from the Vessel Wall II. V2 in like manner corresponds to the reflected radiation R2 from the object or material in the vessel. As indicated, the biasing means, in the form of the battery 23 acting between the grounded line 29 and the resistor and condenser in parallel, is of a value Vb corresponding to but opposing the vessel wall reflected portion VI of the direct current signal, whereby the resulting direct current signal V2 is applied through the line 25 to the amplifier 26 giving a direct current signal V21 connected through the line 2l to a suitable indicator 28 actuable thereby.

As indicated in more detail hereinafter the 4. biasing means effects cancellation of undesired components of the signal pulses and is not necessary in cases where one is not confronted with the problems of interfering reflections such as in the case where the object being subjected to radiation is directly in the path of radiation from the source and is between the source and the fluorescent body. In such cases, also, the indicator may be of the class not only indicating the mere presence of the signal V21 but also capable of indicating its magnitude whereby the thickness, density and certain other characteristics of an object may be determined. In more detail, one practical form of instrument which may be fabricated in portable form is illustrated in Figures 2 to 5 and embodies two main components, a detector head 29 illustrated in Figures 2 to 4 and an ampliner and indicating unit 3S, the essentials of the main stages of which are illustrated in Figure Y5.

Referring to Figure 2, the electronic circuit components of the detector head I0 comprises a photo-'multiplier class of photo-electric vacuum tube 3l having a photo-sensitive cathode 32, an anode 33 and a plurality of diodes 34. Adjacent the cathode and on the Vouter surfaces of the tube envelope 35 is mounted a body o-f thalliumimpregnated sodium iodide as a fluorescent body 36. The outer surface 3l of this body is disposed in the housing of the detector head in exposed relation having a thin mirror surface thereon such as a thin coating of silver. The inner surface 38 of this body is cemented to the glass of envelope 35 of the tube by means of a suitable cement such as Canada balsam,having an index of refraction between the index of refraction ofthe glass of the envelope and the index of refraction of the fluorescent body.

The photo-multiplier tube 3l is coupled in a conventional manner through condenser 39 and resistor 40 through the grid 4I of a triode 42 orequivalent having an anode 43 and a cathode 44. The photo-multiplier tube has a separate source of high voltage supplied at the terminal 45, the terminal 4t representing the high voltage line for the following amplifier illustrated in Fig-e ure 5. The signal puses Eo are derived from terminals 4l and 48 in series with--the cathode resistor 49 and the ground connection 50 in ja cath-- ode follower system whereby a relatively longs connecting cable may extend from the detector.A

illustrated Fighead to the following stages ure 5.

The detector head 29 in its mechanical conf. struction may be of the form illustrated in Fig ures 3 and 4 wherein the components are housed within the casing 29a. A lead body 23h supports.-

the gamma ray source 29o in the manner illustrated in Figure 1.

wall 36a. The casing 29a preferably carries a pair of Wheels 37a to assist in determining thev relative positions of the source of gamma radiation, the tank wall and the fluorescent body 36.-.

A suitable handle 33a fastens to the casing which latter mounts all of the components shown in Figure 2, the handle serving, if desired, as atube through which a connecting.cable may pass to the indicating unit 30.

The photo-multiplier elec-1; tronic tube 3I has mounted thereon the uores-f' cent body 36 disposed in the opening 3m to` receive reected radiations from Within the-tank' geraete 5. an .overau gain .control on all stages and from which thevsignalis `fed to the-grid 52,- a pair of triodes 53 andy 54 within the same envelope 55 having anodes L56 and 51, cathodes 58 and 59,v and a second grid 60. The cathode endof thecircuitry is known as a long tail pair which eiects a non-saturable lmethod of amplification when driven by negative input pulses. It will be observed that the signal pulses applied to the grid` 52 are derived from the cathode follower amplifier tube 42 (Figure 2).

The cathodes 58, 59 are connected to ground through three series resistors 6|,` 62 and 63, the grid resistor 64 connecting to a point between resistors 6| and 62 determines the bias of 'the iirst grid 52, the bias of the Second-grid66 being determined by the potential at the juncture of resistors 62 and 63.

rIhe cathode resistance is divided into-three separate resistors 6|, 62 and 63 to provide separate bias points for the grids 52 and 60 respectively, wherein the second grid 60 is in effect less positive than the grid 52. The grid leak 65establishes a direct current connection between the second grid 60 and the biasing potential established between the resistors 62 and 63. Condenser 66 is a by-pass condenser maintaining the voltage on the grid 60 at a constant value independent of signal.

In operation, the negative signal on the grid 52 causes a corresponding negative signal on the pair of cathodes 58, 59. IThis is the equivalent of a positive signal on the grid 66 causing current to flow through the anode or plate resistor 61 and giving rise to a negative signal on plate 51. It is clear from the operation whereby negative signals are fed in on the grid 52 and negative signals are extracted on plate 51 that any number of these stages could be added in series without upsetting the phase relationship in the circuit and that since the grid 66 is held iixed and the cathode 59 cannot be depressed below 0 volts, there is a limit to the pulse size that can arise on plate 51 independent of the size of pulse fed into grid 52. In effect the original pulses represented at (a) regardless of their magnitude are converted to pulses 68 of relatively uniform magnitude having a random noise level 69 running therethrough.

A wave shaping and discriminating stage 10 follows and serves to convert the desired pulses 68 into the square wave form 1| illustrated at C at the same time eliminating noise by discrimination method. In operation, a square wave is produced for each pulse 68 of a magnitude rising above the ldiscriminating value.

The wave shaping and discriminating stage is comprised of a pair of triodes 12 and 13 within the same envelope 14 having the commonly connected cathodes 15 and 16 opposing anodes 11 and 18 respectively. The negative signal on grid 19 is amplified in tube 12 to produce a positive signal on anode 11. This positive signal in turn is fed to grid 80 through the condenser 8|. The increased potential on grid S0 causes current to flow in tube 13 decreasing the anode volts on the plate 18 and increasing the volts on the common cathode 16. This increase in cathode volts acts back on tube 12 to further shut oiT the current being passed and the action triggered in this manner reduces the current through tube 12 to a small value and increases the current in tube 13 to maximum value determined by the plate supply volts. Thus the magnitude of the output pulse is determined-by the current capacity' of tube" 13 and'the'value Acf the anode or plate resistance 82.-

'Iube 713r1snorma`llyheld` in. a non-conducting state by the biased potentiometer 83 in the Avoltage divider network 84 which sets the potential of grid 18 through grid lead -85 atlv a lvalue from ten to sixty voltsbelow the potentialv of the common cathodes- 15 and 16. Consequently pulses on the input grid 19 whose magnitude when amplified in tube 12 and transmitted to grid 18 are insufficient to initiate the trigger action and are not passed on as pulses to the subsequent part of the circuit. The square waves 1| are converted to a direct current signal pro` portional vto the magnitude of the-square waves and the number genera-ted per second by an integrating stage `86 comprising a pair of diczdes 81 and 88 to which the signal voltage is lamclied at 'the cathode 89 `oi `one and the anode 90 of the other, and the resistor 93 and condenser 94.v Theremaning anode A9| and cathode 92 `of the respective diodesY are connected to the resistor 93 and condenser '94 `disposed inv parallel thereacross, the diodes serving as an alternating current' coupling mechanism to` the resistor'-corr--Vv denser combination having values' of one niegohm and two microfarads respectively, `being together of an essential time `constant-Igreater than one-tenth oi a second 'and of vthe order of two seconds in the presentinstance.V

A substantially non-pulsating formoi direct current of the form illustrated at I(d) having components Vl plus V2 Vis developed on the resistor 93 but 'wherein the4 overal-l volltage developed ybetween the grid 95` and the output amplifying stage v96and ground corresponds only to the desired portion of the signal voltage. Accordingly, biasing means in the form of a potentiometer 91 in the voltage dividing network 94 serves to establish a positive biasing on grid 95 as represented at (e) whereby the desired signal voltage V2 alone arrives at the grid 95.

The output stage 96 involves a pair of triodes 98 and 99 having the commonly joined cathodes |00 and |0| opposing anodes |02 and |03 respectively. The negative voltage on grid 95 is amplified in tube 98 to a larger positive voltage 0n anode |02. This voltage is direct current coupled through resistor |04 to grid |05 of tube 99. This signal is used to turn on current in tube 99 to actuate relay |06 which in turn actuates the indicator mechanism |01. The tube 99 is held in a normally non-conducting state by the biased battery |08 in conjunction with the coupling resistor |09 and |04.

What we claim as our invention is:

l. Apparatus for determining the level of material in a vessel, comprising in combination: a source of gamma radiation of an activity between ve and fty millicuries, a iiuorescent body adapted to emit light energy when excited by beta or gamma radiation and being substantially transparent to said light energy, a photosensitive device for converting said light energy to electrical energy in the form of signal pulses corresponding to reflected radiation pulses from the wall of the vessel and the material therein, an electrical resistor and capacitor disposed electrically in parallel of a time constant greater than one-tenth of a second, means for applying said signal pulses to said resistor and capacitor to convert the signal pulses to a direct current signal proportional to the mean value of the signal pulses, and means including an independent source oi direct current for biasing said converting pulses of radiation coming from the.

object into light energy, the latter being of a pulse form corresponding to the pulse form of the radiation coming from the object; converting the light energy to electricall energy in the form of signal pulses corresponding to the pulses` of radiation from the object; amplifying said signal pulses to a predetermined substantially constant amplitude independent of the relative amplitudes of the original signal pulses; integrating said ampliled signal pulses to obtain a signal voltage substantially proportional inl amplitude to the mean value of said signal pulses.

3. The method of determining the presence of a primary object by measuring radiation reflected therefrom and directed thereto by a radiation emitter and wherein said object is associated with another object of a background nature giving rise to a large signal of background reflected radiation, comprising: converting the pulses of radiation coming from the objects to electrical energy in the form of corresponding signal pulses; amplifying all of said electrical signal pulses to a value less than the amplitude of the smallest background pulse but greater than the amplitude of the largest pulse corresponding to radiation coming from the primary object; and

. integrating said signal pulses after amplication substantially a change in the amount of reected radiation coming from the primary object.

4. A nuclear radiation measuring device adapted to measure a primary object signal of small magnitude, as compared with a relatively large background signal mixed therewith, and comprising: means for detecting nuclear radiation; means for converting the detected nuclear radiation into electrical signal pulses of magnitudes corresponding to the magnitudes of the said background signal and the said primary ob'- ject signal means for amplifying said electrical signal pulses to a predetermined substantially constant amplitude at which the amplitude of those pulses representing radiation from the primary object are of signicant magnitude as compared With the resulting substantially constant amplitude of signal pulses corresponding to back-V ground radiation; means for integrating said amplified signal pulses and means for indicating the variation in amplitude of the mean value of the integrated signal pulses. i

5. The combination claimed in claim 4 wherein the integrating means has a time constant greater than one tenth of a second; and biasing means for removing an unwanted component of the integrated electrical pulses.

References Cited in the le of this patent UNITED STATES PATENTS Number Name Date Re. 22,531 Hare Aug. 22, 1944 2,348,810 Hare May 15, 1944 2,483,139 Herzog Sept. 27, 1949 2,486,946 Herzog Nov. 1, 1949 2,517,404 Morton Aug. l, 1950 2,534,932 Sun Dec. 19, 1950 

